Announcements Chapter 1: 1.7, 1.8. 1.9, 1.27, 1.31, 1.35, 1.39, *1.43, 1.55, 1.59, 1.65, *1.67, 1.69* Chapter 2: 2.17, 2.19, 2.25, 2.46, 2.85, 2.89, *2.95, 2.99, 2.101, 2.103, *2.105* Chapter 3: *3.7,* 3.11, 3.13, 3.15, 3.17, 3.19, 3.26, 3.29, 3.34,3.36,3.38, 3.42, *3.45,* 3.52, *3.56*, 3.62, 3.64, 3.66, 3.72, 3.74, 3.82, 3.88,*****3.93, 3.95, 3.97, 3.99, 3.101,3.114, 3.118, 3.119* Chapter 4: 4.11, 4.13, 4.15, 4.17(except b), *4.19, 4.21, 4.32, 4.46, 4.50,4.52* Common homework assignment for all sections that will be gone over at recitation.
Recitation Schedule Cluster 1: MAC and ECE (Section B/E/F) Tuesday 5-6 PM SEC A 116 A (55 students) SEC A 124 A (55 students) Cluster 2: Bio and Life Science (Section C/D) Wednesday 5-6 PM C-109 (80 students) Cluster 3: Health Science (Section J/K/L) Thursday 5-6 PM CTC-102 (80 students) CTC-103 (40 students) Cluster 4: Psychology (Section G/H/I) Friday 3:30-4:30 SEC B 201 A (80 students) SEC C 201 A (80 students)
Learning Goals: Chapter 2 1. Little history Dalton s Atomic Theory and the structure of the atom 2. Modern Atomic Theory and Years of Observation and Experimentation 3. Atomic Number, Mass Number, and Isotopes 4. The Periodic Table 5. Molecules/Compounds/Chemical formulas 6. Naming ionic and covalent compounds
Atomic Theory accounts for Law of Definite Composition Conservation of Mass Law of Multiple Proportions explained by Atomic Structure that have with the same number of protons comprising Nucleus Electrons containing constitute most of an atoms protons and neutrons possessed by all Compounds which are either with a different number of neutrons Isotopes Ionic Compounds Covalent Compounds made from reactions between made from reactions between volume symbolized by Metals give rise to A nuclear properties chemical process Elements Atoms chemical properties Z X Non-metals that loose electrons that gain electrons cations anions Non-metals that we call Molecules exploited in that explains radioactivity, fission and atomic bombs symbolized by symbolized by chemical formula molecular formula
Centuries of investigation brought about undeniable observations (laws) about matter. -400BC: Democritus: matter is made of tiny indivisible particles, called "atomos" 1789: Lavoisier--the mass of substances before and after a chemical reaction the same: "The Law of Conservation Mass." >17 elements known 1799: Proust--different samples of the same compound contain the same elements in the same proportion by mass = The Law of Constant Composition 1800: Dalton--When atoms combined to form compounds they do so in ratio of whole numbers. The Law of Constant Composition
Law of Conservation of Mass: there is no change in mass when a chemical reaction occurs in a closed system (no matter escapes). calcium oxide + carbon dioxide calcium carbonate CaO + CO 2 CaCO 3 56.08g + 44.00g 100.08g 1 Ca Atom + 1 O Atom + 1 C Atom + 2 O Atom 1 Ca Atom + 1 C Atom + 3 O Atom reactant 1 + reactant 2 product total mass = total mass Macroscopic View
The Law Conservation of Mass forms the basis for balanced chemical equations in chemistry. 16 X + 8 Y 8 X 2 Y # and mass of reactant atoms = # and mass atoms of products
Atomic Theory accounts for Law of Definite Composition Conservation of Mass Law of Multiple Proportions explained by Atomic Structure that have with the same number of protons comprising Nucleus Electrons containing constitute most of an atoms protons and neutrons possessed by all Compounds which are either with a different number of neutrons Isotopes Ionic Compounds Covalent Compounds made from reactions between made from reactions between volume symbolized by Metals give rise to A nuclear properties chemical process Elements Atoms chemical properties Z X Non-metals that loose electrons that gain electrons cations anions Non-metals that we call Molecules exploited in that explains radioactivity, fission and atomic bombs symbolized by symbolized by chemical formula molecular formula
The Law of Constant Composition says that a pure compound is composed of the same elements in the same fraction by mass no matter where that compound originates. H2O (Philippines) = H2O (Alaska) = H2O (South Pole) Calcium carbonate = CaCO3 Analysis by Mass (grams/20.0g) 8.0 g calcium 2.4 g carbon 9.6 g oxygen Mass Fraction (parts/1.00 part) 0.40 calcium 0.12 carbon 0.48 oxygen Percent by Mass (parts/100 parts) 40% calcium 12% carbon 48% oxygen 20.0 g 1.00 part by mass 100% by mass
Law of Multiple Proportion says that atoms are discrete whole numbered entities (not fractional) and react with other atoms in whole numbers. Example: Carbon Oxides A & B Assume 100 g of each compound. Carbon Oxide I : 57.1% oxygen and 42.9% carbon Carbon Oxide II : 72.7% oxygen and 27.3% carbon g O = 57.1 g for oxide I & 72.7 g for oxide II g O 57.1 g C = 42.9 = 1.33 g C = 42.9 g for oxide I & 27.3 g for oxide II g O g C = 72.7 27.3 = 2.66 2.66 g O/g C in II 1.33 g O/g C in I = 2 1
Problem Example Nitrogen and hydrogen form many compounds, some of which involve other elements as well. The mass of hydrogen that combines with 1.00 g of nitrogen to form three of these compounds are: urea, 0.1428 g; ammonia, 0.0714 g; ammonium chloride, 0.2857 g. Show that this data is consistent with the Law of Multiple Proportions. Compound Chemical Formula Mass Ratio H:N Ratio to 0.0714 Urea CONH 2 0.1428 2:1 Ammonia NH 3 0.0714 1:1 Ammonium Chloride NH 4 Cl 0.2857 4:1
Assume that the mixture of substances in drawing (a) undergoes a reaction. Which of the drawings b or c or d represents a product mixture consistent with the law of mass conservation?
If red and blue spheres represent atoms of different elements, which two of the following drawings illustrate the law of multiple proportions?
Dalton s Atomic Theory 1803 1. An element is composed of many unique indivisible particles called atoms that can not be converted to other atoms. 2. Atoms of a given element have a unique and identical mass and behave alike in all properties. (i.e...different elements have different masses because they are different atoms). 3. Atoms are indestructible and retain their chemical identity and mass in undergoing a chemical reaction (conservation of mass). 4. Chemical combination (a reaction) of elements to make different compounds occurs when atoms join together in whole-number ratios (proportions).
Key experimental observations that supported Atomic Theory.
1906: J.J. Thomson discovers a beam particles called cathode rays that are determined to be negatively charged particles that we now know are electrons. He determines the charge/mass ratio of a single electron to be 1.76 x 10 8 C/g. Cathode Rays are deflected by magnetic field. Rays must be charged Rays are deflected towards the + plate. All CRT s display this property
1909: Milikan determines the charge of an electron to be 1.60 10-19 C and uses this value to calculate the the mass of an electron: 9.11 10-28 g Millikan determines charge on the electron = 1.60 10-19 C. Knowing the charge to mass ratio from Thompson, 1.76 10 8 C/g, Millikan calculates the mass of the electron: 9.10 10-28 g. Later with more precise measurements scientists measure the mass of the electron to be: 9.10939 10-28 g.
Rutherford Finds Evidence For Nucleus and a positively charged center. 1911: Rutherford fires positively charged α-particles at a piece of gold foil. Most of the α-particles pass straight through the foil without deflection and are seen by a detector which surrounded the gold foil. Some α-particles were deflected at high angles indicating a small but real positively charged center in the foil. The deflected particles give solid proof for + charged center or nucleus. Incident α-particles Nucleus of Au atom Atoms of Gold Foil
1932 Chadwick Discovers Neutron H atom: 1 p + vs He atom: 2 p+ mass He/mass H should = 2 but the measured mass He/mass H = 4 It took many years however to figure out why Helium to hydrogen mass was 4:1 and not 2:1 α + 9 Be 1 n + 12 C + energy neutron (n) is neutral (charge = 0) n mass ~ p mass = 1.67 x 10-24 g
Modern atomic theory: atoms have a common structure that consists of a central nucleus containing positively charged protons and neutrally charged neutrons surrounded by a cloud of negatively charged electrons. p + and n 0 in the nucleus and make up nearly all the mass. e - are located outside of the nucleus and account for the volume and chemistry of the atom. If the atom is the Houston Astrodome, then the nucleus is a marble on the 50-yard line.
The mass and charge of subatomic particles have all been measured and are known. Nearly all of the atom s mass is located in the nucleus, nearly all the volume is occupied by electrons. Mass p + = mass n 0 = 1840 x Mass e -
Pinheads have a diameter of about 1 mm (1.00 x 10-3 meters). If an atom has a diameter of 2.5 x 10-10 meters, then Head of Pin Atoms lined up # Atoms = 1 mm 1 m 1000 mm 1 atom 2.5 10 10 m = 4 106 atoms ~4,000,000 atoms are lined up side by side across the head of a pin.
Atomic Theory accounts for Law of Definite Composition Conservation of Mass Law of Multiple Proportions explained by Atomic Structure that have with the same number of protons comprising Nucleus Electrons containing constitute most of an atoms protons and neutrons possessed by all Compounds which are either with a different number of neutrons Isotopes Ionic Compounds Covalent Compounds made from reactions between made from reactions between volume symbolized by Metals give rise to A nuclear properties chemical process Elements Atoms chemical properties Z X Non-metals that loose electrons that gain electrons cations anions Non-metals that we call Molecules exploited in that explains radioactivity, fission and atomic bombs symbolized by symbolized by chemical formula molecular formula
The Periodic Table organizes 114 elements (92 naturally occurring the rest man-made) according to increasing atomic number (# of protons). Periodicity appears in members in each vertical column called a Group.
The Periodic Table of the Elements is a summary of number of protons, neutrons and electrons built up by adding a protons and neutrons to the nucleus and electrons outside the nucleus to keep the atom electronically stable. Nucleus (not scaled to size)! 1e - 2e - 3e - 4e - 5e - H 1p + 0n 0 He 2p + 2n 0 Li 3p + 3n 0 Be 4p + 4n 0 B 5p + 5n 0 C 6p + 6n 0 N 7p + 7n 0 O 8p + 8n 0 F 9p + 9n 0 Ne 10p + 10n 0 6e - 7e - 8e - 9e - 10e -
Elements are either metals, metalloids, and nonmetals and show in a specific region in the periodic table. Cadmium Metalloids Non-Metals Metals Bromine Iodine
Covalent compounds result from chemical reactions between atoms or elements of non-metals. Cadmium Metalloids Non-Metals Metals Bromine Iodine
An ionic compound (salt) results from the chemical reaction between atoms or elements of a metal (cation) and non-metal (anion). Cadmium Non-Metals Metals Bromine Iodine
Alkali Metals Alkaline Earths Transition Metals Halogens Main Group Noble Gases Main Group Lanthanides and Actinides
Many elements occur in nature as molecules and not as discrete elements as written in the Periodic Table. Know these molecular compounds as it prevent confusion! 1A 2A 3A 4A 5A 6A 7A 8A (1) (2) (13) (14) (15) (16) (17) (18) H 2 N 2 O 2 F 2 P 4 S 8 Cl 2 Se 8 Br 2 I 2 tetratomic molecules octatomic molecules diatomic molecules
Atomic Masses are isotopic averages and not the mass of a single nucleui
Isotopes are atoms that have the same number of protons as their parent element, but they are found to have a different number of neutrons in the nucleus. All known elements are not pure isotopes but they are mixtures of isotopes!
All elements exist as a mixture of isotopes (shown in red highlight below) not as a single pure nucleus.
Chemists use a short-hand notation to communicate information about isotopes or nuclides of atoms. # p + + # n 0 Mass Number Atomic Number # p + A X Z Atomic Symbol
Atomic Masses are isotopic averages and not the mass of a single nuclei
Do You Understand Isotopes? How many neutrons, protons and electrons are in each of the following nuclides? 12 C 6 16 O 8 Mass Number = p + + n 0 Atomic number = p + 238 92U
Do You Understand Nuclide Notation? The atomic number of the element Silicon (Si) is 14. Si has three naturally occurring isotopes: 28 Si, 29 Si, and 30 Si. How many protons, neutrons, and electrons in each silicon isotope. PLAN: Use the atomic number and atomic masses to compute. The atomic number of silicon is 14. Therefore 28 Si has 14p +, 14e - and 14n 0 (28-14) 29 Si has 14p +, 14e - and 15n 0 (29-14) 30 Si has 14p +, 14e - and 16n 0 (30-14)